WO2006067102A2

WO2006067102A2 - Glass sheet bearing a multilayer stack

Info

Publication number: WO2006067102A2
Application number: PCT/EP2005/056894
Authority: WO
Inventors: Daniel Decroupet; Jean-Michel Depauw
Original assignee: Glaverbel
Priority date: 2004-12-21
Filing date: 2005-12-19
Publication date: 2006-06-29
Also published as: RU2007127629A; RU2431621C2; EP1833768A2; PL1833768T3; WO2006067102A3; EP1833768B1

Abstract

The invention relates to a glass sheet bearing a multilayer stack comprising at least one functional layer which is based on a material that reflects infrared radiation and at least two dielectric coatings, such that each functional layer is surrounded by dielectric coatings. According to the invention, the dielectric coatings include at least one layer that is based on a mixed zinc/tin oxide containing at least 20 % tin and at least one oxygen diffusion barrier layer with a thickness of more than 5 nm. The inventive glass sheet can form the basis of glazing with high thermal insulation, which is very useful, for example, in the building and automotive industries.

Description

Glass sheet carrying a multi-layer stack

The invention relates to a sheet of glass carrying a multilayer stack, deposited by sputtering under reduced pressure, comprising at least one functional layer based on an infrared radiation reflecting material and at least two dielectric coatings, each functional layer being surrounded by dielectric coatings, which is capable of undergoing or having undergone a heat treatment at elevated temperature, such as a bending, annealing or thermal quenching operation. The invention also relates to a laminated glazing unit and to a multiple glazing unit comprising such a glass sheet.

Glazing comprising a sheet of glass carrying a multilayer stack referred to in the present invention are used in particular to improve the thermal insulation of large glazed surfaces and thus reduce energy losses and heating costs in cold weather. Multilayer stacking is a low-emissivity coating that reduces heat loss by long-wave infrared radiation. It is generally required that it has a very high light transmission (TL).

These windows are also used as sunscreen to reduce the risk of overheating, an enclosed space with large windows, due to sunshine and reduce the air conditioning effort to consent in summer. In this case, the glazing must let as little as possible of total solar energy radiation, that is to say it must have a solar factor (FS) the lowest possible. However, it is highly desirable that it ensures as high a light transmission (TL) as possible so as to provide a sufficient level of illumination inside the building or inside the motor vehicle. These somewhat conflicting requirements reflect the desire to obtain a glazing having a high selectivity (S), defined by the ratio of light transmission to solar factor.

The light transmission (TL) is the percentage of the incident luminous flux, Illuminant D65, transmitted by the glazing. The solar factor (FS or g) is the percentage of incident energy radiation which is firstly directly transmitted by the glazing and secondly absorbed by the latter and then radiated by its opposite side to the energy source.

For use in buildings, they are generally assembled in double glazing associated with another sheet of glass, free or uncoated, the multilayer coating being within the space between the two sheets of glass. When used in the automotive field, they are generally laminated to another sheet of glass, with or without a coating, by means of a thermoplastic film such as PVB, the multilayer coating lying between them. two sheets of glass.

It is also desirable that the glazings meet certain aesthetic criteria in terms of light reflection (RL), that is to say the percentage of the incident luminous flux of the illuminant D65 reflected by the glazing, and of color in color. reflection and transmission. The combination of high selectivity with low light reflection sometimes leads to purple shades in reflection which are very unattractive.

In the field of building, it is often necessary to carry out a mechanical reinforcement operation of the glazing, such as thermal quenching, to improve its resistance to mechanical stresses. In the automotive field, it is also often necessary to bend the glazing to comply with the characteristics of the vehicle. In glazing manufacturing and shaping processes, there are certain advantages to performing these quenching and bending operations on the already coated substrate instead of coating an already shaped substrate. These operations are carried out at a relatively high temperature, at which temperature the infrared reflective layer, for example based on silver, has a tendency to deteriorate and lose its optical properties and its properties with respect to infrared radiation. . It is therefore necessary to take special precautions to achieve a coating structure that is capable of undergoing heat treatment tempering or bending, often referenced hereinafter by the expression "bombable-soakable", without losing its optical properties eVou energetic that make it its raison d'être, whether for glazing protection solar, for glazing intended to improve the thermal insulation or for glazing which has the role of performing at the same time these two thermal functions.

To solve this problem, various solutions have been proposed. EP 275 474 B1, for example, proposes to use dielectric coatings in the form of metal oxides obtained by sputtering in an oxidizing atmosphere from zinc-tin targets, and to surround the infrared reflective layer based on of silver by thin metallic layers of titanium. Patent Application WO 01/27050 A1 proposes the use of dielectric coatings formed of at least two layers of different composition, one of which, arranged specifically in the stack, is a particular mixture of zinc oxide with an additional material. The patent application WO 03/022770 A1 proposes a structure of the type Si ₃ N ₄ ZNiCrNxZAgZNiCr or NiCrNxZSi ₃ N ₄ with dielectric coatings formed by silicon nitride.

These proposals give acceptable results, but the quality of the layers obtained can be further improved in certain aspects, in particular as regards the chemical durability eVo resistance to heat treatment at very high temperature and emissivity.

The invention relates to a sheet of glass carrying a multilayer stack comprising at least one functional layer based on an infrared radiation reflecting material and at least two dielectric coatings, each functional layer being surrounded by dielectric coatings, characterized in that the set of dielectric coatings includes at least one zinc-tin mixed oxide-based layer containing at least 20% tin and at least one oxygen diffusion barrier layer of more than 5 nm thickness chosen from among the following materials: AlN, AlNxOy, Si ₃ N ₄ , SiOxNy, ZrN, SiC, SiOxCy, TaC, TiN, TiNxOy, TiC, CrC, DLC ("Diamond like Carbon") and their alloys, and nitrides or oxy-nitrides of alloys such as SiAlOxNy or SiTixNy.

It has been discovered that a stack containing in combination a zinc-tin mixed oxide containing at least 20% tin with at least one oxygen diffusion barrier layer, according to the conditions specified in claim 1, provides some benefits in terms of chemical durability or resistance to heat treatment compared to the previously known stacks, depending on the arrangement of the different layers in the stack as explained below. It is surprising that such an association brings specific benefits.

The terms "zinc-tin mixed oxide containing at least 20% tin" used in the present description mean that there is at least 20% by weight of tin in the zinc-tin mixed oxide with respect to total weight of zinc and tin in the mixed oxide. It is the same for the percentages of zinc in the mixed oxide given below, as well as for other values than 20% which is taken here by way of illustration. A convenient way of forming the zinc-tin mixed oxide, referred to herein, is to use a cathode of a zinc-tin metal alloy of the composition suitable for magnetic field assisted sputtering. magnetron type, at reduced pressure in a reactive atmosphere consisting of an oxygen-argon mixture.

Preferably, the oxygen diffusion barrier layer has a physical thickness of between 5 and 100 nm, advantageously between 12 and 80 nm, and in some applications it is between 12 and 50 nm. These ranges of thicknesses make it possible to provide an effective barrier to the diffusion of oxygen while constituting an anti-reflective dielectric particularly useful in the overall interference effect. Preferably, the layer based on a zinc-tin mixed oxide containing at least 20% tin has a physical thickness of between 10 and 100 nm, advantageously between 20 and 85 nm. Under this thickness, this zinc-tin mixed oxide not only plays a favorable role in the interferential effect, but it also seems to play a particularly effective role in the thermal resistance of the coating when it undergoes a heat treatment at high temperature, as well as in the resistance of the coating to chemical aggressions.

Advantageously, a ZnO-based layer is disposed under and in direct contact with the or at least one functional layer, and preferably in contact with each functional layer. A ZnO-based layer, even of small thickness, under the functional layer significantly improves the resistance to oxidation and chemical degradation of the functional layer, especially when it is based on money.

Preferably, at least one functional layer is deposited on and in direct contact with a zinc-tin mixed oxide or suboxide oxide layer comprising 80 to 99% zinc and 1 to 20% zinc. another material selected from Mg, Si, Ti, Zr, Hf, Nb, Ta, Cr, Mo, W, Al, Ga, In and Bi, forming part of the dielectric coating disposed under the functional layer. It has been found that by applying this feature, regardless of the arrangement of the tin-zinc alloy mixed oxide layer (s) containing at least 20% tin and the barrier layer (s), it is found that clearly the properties of the functional layer based on a material reflecting the infrared radiation in the finished product, and especially after heat treatment. The presence of a high content of zinc, but less than 100%, in contact with the infrared reflecting material, particularly when it is a silver-based material, seems to be a determining factor for this material is more resistant to chemical attack and has a more adequate structure for the reflection of infrared radiation, both solar (near infrared) and infrared long wave (far infrared). This advantage is clearer for the entire stack if each functional layer is disposed in this way.

Preferably, the dielectric coating (hereinafter referred to as "lower dielectric") disposed between the substrate and the functional layer or the first functional layer, if there are more than one, comprises at least one layer based on a mixed oxide zinc tin containing at least 20% tin. It has been found that this arrangement makes the stack less sensitive to the surface condition of the glass and the diffusion of elements from the surface of the glass. A particularly interesting advantage of this arrangement is that the properties and quality of the stacking does not depend much on the fact that the base glass sheet has just been manufactured or has been stored for a long time, for example. example several months before its introduction into the layer deposition device. The layer based on a zinc-tin mixed oxide containing at least 20% tin does not have to be in direct contact with the substrate to obtain this advantageous result. An underlayer, formed for example of TiO ₂ , ZnO, SiO ₂ , Al ₂ O ₃ , AlN or SnO ₂ , their mixture or any suitable dielectric, can be inserted between the substrate and said layer. However, it has been found that the best result can be obtained when said layer based on a zinc-tin mixed oxide containing at least 20% tin is deposited directly on the substrate. Preferably, the dielectric coating (hereinafter referred to as

"Higher dielectric") disposed above the functional layer or the last functional layer, if there are more than one, comprises at least one said barrier layer for the diffusion of oxygen. With this arrangement, it is found that the optical and energy properties are more stable during the heat treatment. In particular, the hue in reflection evolves less during a quenching or bending treatment. This makes it possible, in particular, to obtain more easily glazings after quenching which can be associated with non-tempered glazings having the same structure, without any significant difference from the aesthetic point of view. Advantageously, in addition to the oxygen diffusion barrier layer, the upper dielectric comprises at least one layer based on a zinc-tin mixed oxide, containing at least 20% of tin, deposited under the diaper. barrier of the upper dielectric. This improves the chemical resistance of the stack especially when the coated glazing is stored under critical conditions with respect to chemical attack, the chemical durability of the glazing is extended. It thus becomes possible to soak a sheet of glass carrying a stack which has been stored for some time since the deposit of the stack, which otherwise is a risk of occurrence of defects during the quenching operation. Advantageously, in addition to this specific arrangement, the lower dielectric comprises at least one layer based on a zinc-tin mixed oxide containing at least 20% tin. It is thus noted that the stack is, moreover, insensitive to the surface condition of the glass.

Preferably, the multilayer stack comprises at least two functional layers based on a material reflecting the infrared radiation and in that the or at least one dielectric coating (hereinafter referred to as "intermediate dielectric") arranged between two functional layers comprises at least one layer based on a zinc-tin mixed oxide, containing at least 20% tin. High-performance, highly heat-resistant, high-resistance anti-solar glazings with good structural stability are thus easily obtained. It seems indeed that an intermediate dielectric comprising such a layer based on a zinc-tin mixed oxide limits inter-scattering in the stack.

Preferably, the functional layer (s) based on an infrared radiation reflecting material are based on silver or a silver alloy. Silver is a material well suited to sputter an infrared reflecting layer and is less expensive than gold. The silver can be doped with a small amount of another noble metal such as palladium, platinum or rhodium. It can also be in the form of an alloy with another metal such as aluminum or copper, for example.

Preferably, each silver-based functional layer is surmounted by at least one protective layer selected from one or more of the following materials: Ti, TiOx, NiCr, NiCrOx, Nb, Ta, Al, Zr or ZnAl. The protective layers are intended to protect the silver-based layers, especially during the heat treatment, but also during the deposition of the upper dielectric layers, especially if they are formed in an oxygen-containing atmosphere that would risk to oxidize silver or in an atmosphere containing nitrogen. They are sometimes also called sacrificial layers because they oxidize instead of silver, and thus they themselves become more transparent. For example, a Ti protective layer will form TiO ₂ at the time of deposit. a dielectric in an oxidizing atmosphere above the protective layer. A TiOx layer may, for example, be deposited from a TiOx ceramic target in a neutral atmosphere of argon. It can also be oxidized more completely by the plasma used for the deposition of the next layer, if it is a layer deposited in an oxidizing atmosphere.

Preferably, the layer (s) - barrier (s) to the diffusion of oxygen is or are based on Si ₃ N ₄ , SiOxNy, AlN or AlOxNy. These materials form excellent barriers to oxygen diffusion and significantly improve the thermal resistance of the coating. Moreover, when they are arranged in the upper dielectric, they reduce by the amount of oxide present in the stack above the or functional layers, which reduces the evolution of the properties of the stack during heat treatment. It is therefore possible to coat glass sheets of different thicknesses and obtain the same properties without modifying the structure of the stack, in particular without having to adjust the thickness of the protective layers if they are present.

The invention extends to a tempered glass sheet and / or curved formed of a sheet of glass carrying a multilayer stack, as defined above, which has undergone a heat treatment eVou tempering bending after deposition of the stacking on the glass.

The invention also extends to a laminated glazing unit comprising at least one glass sheet as defined above assembled with at least one other glass sheet by means of a PVB film, which is particularly suitable for the field of glazing for the automotive industry, as well as multiple glazing comprising at least one glass sheet as defined above maintained spaced hermetically from at least one other sheet of glass by a spacer attached to the periphery between the glass sheets.

The invention will now be described in more detail, in a nonlimiting manner, using the examples of preferred embodiments below. Examples:

Example 1

A plain soda-lime float glass sheet 2 m by 1 m and 4 mm thick is placed in a cathodic sputtering device, assisted by a magnetic field, at a reduced pressure (approximately 0.3 Pa). magnetron type. On this glass sheet, a multilayer stack having the following structure is deposited from the glass:

• A lower dielectric coating consisting of two layers: o 26 nm ZnSnOx formed in an oxidizing atmosphere, consisting of a mixture of argon and oxygen, from a cathode of zinc-tin alloy with 52% zinc and 48% tin, to obtain zinc stannate ZnSnO ₄ on the glass; 10 nm ZnAlOx formed in the same oxidizing atmosphere from a zinc-aluminum cathode with 90% zinc and 10% aluminum;

• A functional layer formed of 13 nm of Ag deposited in a neutral atmosphere consisting essentially of argon; A protective layer formed of 5 nm of NiCrOx deposited in a reactive atmosphere in an Ar / O ₂ mixture from a NiCr target;

• A superior dielectric coating consisting of an oxygen diffusion barrier layer formed of 37 nm Si ₃ N ₄ deposited in a reactive atmosphere from a silicon target lightly doped with aluminum to render it sufficiently conductive for sputtering.

The reactive atmosphere is formed of a mixture of nitrogen and argon, for example between 10 and 20% of Ar and 90-80% of nitrogen, so as to obtain a dielectric Si ₃ N ₄ having that a very low light absorption of the same order of magnitude as metal oxides such as ZnO or SnO ₂ . The properties before heat quenching treatment of the coated glass sheet are as follows:

TL = 81.1%; 8 (normal emissivity) = 0.065; Rs = 6.0 Ω / square; the layer-side reflection hue is expressed by the following values: L * = 24.2; a * = -0.4; b * = - 13.2. In the present invention, the light transmission (TL) is measured with Illuminant D65 / 2 °. The hue in reflection is expressed by the CIELAB 1976 values (L * a * b *) measured with Illuminant D65 / 10 ⁰ . The emissivity of a given surface at a given temperature is defined as the ratio of the energy emitted by the surface relative to the perfect emitter (black body: emissivity = 1) at the same temperature. For glazing, the emissivity is often measured at 25 ° C on the coated side of the glass sheet. Rs is the specific resistance expressed in ohms per square (per square unit area).

The glass sheet thus coated then undergoes a thermal quenching operation during which it is subjected for 4 minutes at a temperature of 690 ^° C. and then cooled rapidly by jets of cold air.

The properties after heat quenching treatment of the sheet of coated glass are as follows:

TL = 84.3%; 8 (normal emissivity) = 0.040; Rs = 3.6 Ω / square; the layer-side reflection hue is expressed by the following values: L * = 25.8; a * = -1, 2; b * = - 13 l. Example 2

On a glass sheet identical to Example 1, in the same manner as in Example 1, a multilayer stack having the following structure is deposited from the glass:

• A lower dielectric coating consisting of two layers: o 26 nm ZnSnOx formed in an oxidizing atmosphere, consisting of a mixture of argon and oxygen, from a cathode of zinc-tin alloy with 52% zinc and 48% tin; o 8 nm ZnAlOx formed in the same oxidizing atmosphere from a cathode of a zinc-aluminum alloy with 90% zinc and 10% aluminum; • A functional layer formed of 11 nm of Ag deposited in a neutral atmosphere consisting essentially of argon;

• A protective layer formed of 6 nm of Ti deposited in the same neutral atmosphere from a titanium target, this layer will be partially oxidized by the subsequent deposition which is done in an oxidizing atmosphere;

• An upper dielectric coating consisting of two layers: o 25 nm ZnSnOx formed in an oxidizing atmosphere, consisting of a mixture of argon and oxygen, from a cathode of zinc-tin alloy with 52% zinc and 48% tin; o An oxygen diffusion barrier layer formed of 17 nm of

If ₃ N ₄ deposited in a reactive atmosphere of nitrogen, formed of a mixture of nitrogen and argon as in Example 1, from a silicon target slightly doped with aluminum to make it sufficiently conductor for sputtering; After 24h. in a chamber containing a salt spray, according to the ISO9227 standard applied to diaper glasses, there is no sting and therefore no degradation of the silver-based layer.

The properties before heat quenching treatment of the coated glass sheet are as follows:

TL = 76.9%; 8 (emissivity) = 0.075; Rs = 6.2 Ω / square; the layer-side reflection hue is expressed by the following values: L * = 25.3; a * = -0.9; b * = - 16.6.

The glass sheet thus coated is stored in a humid place for several weeks before then undergo a thermal quenching operation during which it is subjected for 4 minutes at a temperature of 690 ^° C. and then cooled suddenly by air jets cold.

The properties after heat quenching treatment of the coated glass sheet are as follows:

TL = 86.1%; 8 (emissivity) = 0.050; Rs = 4.2 Ω / square; the hue in reflection on the layer side is expressed by the following values: L * = 33.5; a * = -3.8; b * = - 14, l.

It is found that prolonged residence in a humid atmosphere did not impair the ability of the coated glass sheet to be quenched because the final product has excellent properties showing that the functional layer has not been deteriorated. Example 3

• A lower dielectric coating consisting of two layers: o 16 nm AlN formed in a nitrogen atmosphere (80% Ar and 20% N ₂ ) from an aluminum cathode; 12 nm ZnAlOx formed in the same oxidizing atmosphere from a zinc-aluminum cathode with 90% zinc and 10% aluminum;

• A functional layer formed of 12 nm of Ag deposited in a neutral atmosphere consisting essentially of argon;

• A protective layer formed of 7 nm of Ti deposited in the same neutral atmosphere from a titanium target, this layer will be partially oxidized by the subsequent deposition which is done in an oxidizing atmosphere;

• An upper dielectric coating consisting of two layers: o 30 nm ZnSnOx formed in an oxidizing atmosphere, consisting of a mixture of argon and oxygen, from a zinc-tin cathode at 52% zinc and 48% d tin; o An oxygen diffusion barrier layer formed of 10 nm of

If ₃ N ₄ deposited in a reactive atmosphere of nitrogen, formed of a mixture of nitrogen and argon as in Example 1, from a silicon target slightly doped with aluminum to make it sufficiently conductor for sputtering;

The properties before heat quenching treatment of the coated glass sheet are as follows: TL = 68.9%; 8 (emissivity) = 0.068; Rs = 5.8 Ω / square; the hue in reflection on the layer side is expressed by the following values: L * = 22.5; a * = +4.0; b * = - 19.4.

TL = 85%; 8 (emissivity) = 0.044; Rs = 3.8 Ω / square; the layer-side reflection hue is expressed by the following values: L * = 34.1; a * = -4.0; b * = - 16.7. Example 4

On a sheet of glass identical to Example 1, in the same manner as in Example 1, a multilayer stack having the following structure was deposited from the glass: • A lower dielectric coating consisting of three layers: o 12 nm AlN formed in a nitrogen atmosphere (80% Ar and 20% N ₂ ) from an aluminum cathode; 12 nm ZnSnOx formed in an oxidizing atmosphere, consisting of a mixture of argon and oxygen, from a cathode of a zinc-tin alloy with 52% zinc and 48% tin; 10 nm ZnTiOx formed in the same oxidizing atmosphere by DC co-spraying from two rotating cathodes, a zinc cathode and a titanium cathode, to obtain a mixed oxide containing 15% by weight of titanium oxide;

• A functional layer formed of 11 nm of Ag deposited in a neutral atmosphere consisting essentially of argon;

• A protective layer formed of 5 nm of Ti deposited in the same neutral atmosphere from a titanium target, this layer will be partially oxidized by the subsequent deposition which is done in an oxidizing atmosphere; • An intermediate dielectric coating consisting of two layers: o 75 nm ZnSnOx formed in an oxidizing atmosphere, consisting of a mixture of argon and oxygen, from a zinc-tin cathode at 52% zinc and 48% d tin; 10 nm ZnTiOx formed in the same oxidizing atmosphere by DC co-spraying from two rotating cathodes, a zinc cathode and a titanium cathode, to obtain a mixed oxide containing 15% by weight of titanium oxide;

• A functional layer formed of 15 nm of Ag deposited in a neutral atmosphere consisting essentially of argon; • A protective layer formed of 5 nm of Ti deposited in the same neutral atmosphere from a titanium target, this layer will be partially oxidized by the subsequent deposition which is done in an oxidizing atmosphere;

• An upper dielectric coating consisting of two layers: o 12 nm ZnSnOx formed in an oxidizing atmosphere, consisting of a mixture of argon and oxygen, from a zinc-tin cathode at 52% zinc and 48% tin; o An oxygen diffusion barrier layer formed of 17 nm of

TL = 52.2%; ε (emissivity) = 0.028; Rs = 2.7 Ω / square; the hue in reflection on the glass side is expressed by the following values: L * = 38.3; a * = -3.2; b * = - 14.2.

The glass sheet thus coated then undergoes a thermal quenching operation during which it is subjected for 4 minutes at a temperature of 690 ^° C. and then cooled rapidly by jets of cold air. The properties after heat quenching treatment of the coated glass sheet are as follows:

TL = 82.4%; ε (emissivity) = 0.022; Rs = 2.0 Ω / square; the hue in reflection on the layer side is expressed by the following values: L * = 34.7; a * = -0.1; b * = +0.9.

Claims

A sheet of glass carrying a multilayer stack comprising at least one functional layer based on an infrared radiation reflecting material and at least two dielectric coatings, each functional layer being surrounded by dielectric coatings, characterized in that all the coatings dielectric comprises at least one layer based on a zinc-tin mixed oxide containing at least 20% tin and at least one oxygen diffusion barrier layer of more than 5 nm thick selected from the materials following: AlN, AlNxOy, Si ₃ N _4, SiO x N y, ZrN, SiC, SiOxCy, TaC, TiN, TiNxOyJiC, CrC, DLC and alloys thereof, and nitrides or oxynitrides of alloys such as SiAlOxNy or SiTixNy.

2. Glass sheet according to claim 1, characterized in that the oxygen diffusion barrier layer has a physical thickness of between 5 and 100 nm, preferably between 12 and 80 nm.

3. Glass sheet according to claim 2, characterized in that the barrier layer to the diffusion of oxygen has a physical thickness of between 12 and 50 nm.

4. Glass sheet according to one of claims 1 to 3, characterized in that the layer based on a zinc-tin mixed oxide containing at least 20% tin has a physical thickness of between 10 and 100 nm, preferably between 20 and 85 nm.

5. Glass sheet according to one of claims 1 to 4, characterized in that at least one functional layer is deposited on and in direct contact with a layer based on zinc oxide or mixed sub-oxide. tin comprising from 80 to 99% zinc and from 1 to 20% of another material selected from Mg, Si, Ti, Zr, Hf, Nb, Ta, Cr, Mo, W, Al, Ga, In and Bi, forming part of the dielectric coating disposed under the functional layer.

Glass sheet according to claim 5, characterized in that the stack comprises a plurality of functional layers and each functional layer is deposited on and in direct contact with a mixed zinc oxide or suboxide oxide layer. tin comprising 80 to 99% zinc and 1 to 20% of another material selected from Mg, Si, Ti, Zr, Hf, Nb, Ta, Cr, Mo, W, Al, Ga, In and Bi.

7. Glass sheet according to one of claims 1 to 6, characterized in that the dielectric coating (hereinafter referred to as "lower dielectric") disposed between the substrate and the functional layer or the first functional layer if there to at least one layer based on a zinc-tin mixed oxide containing at least 20% tin.

8. Glass sheet according to one of claims 1 to 7, characterized in that the dielectric coating (hereinafter referred to as "upper dielectric") disposed above the functional layer or the last functional layer if there has several, comprises at least one said barrier layer to the diffusion of oxygen.

9. Glass sheet according to claim 8, characterized in that the upper dielectric comprises at least one layer based on a mixed zinc-tin oxide, containing at least 20% tin, deposited under the barrier layer of the dielectric superior.

10. Glass sheet according to claim 9, characterized in that, in addition, the lower dielectric comprises at least one layer based on a zinc-tin mixed oxide containing at least 20% tin.

11. Glass sheet according to one of claims 1 to 10, characterized in that the multilayer stack comprises at least two functional layers based on a material reflecting the infrared radiation and in that the or at least one dielectric coating (hereinafter referred to as "intermediate dielectric") disposed between two functional layers comprises at least one layer based on a zinc-tin mixed oxide, containing at least 20% tin.

12. Glass sheet according to one of claims 1 to 11, characterized in that the or the functional layers based on a material reflecting the infrared radiation are based on silver or a silver alloy.

13. The glass sheet as claimed in claim 12, characterized in that each silver-based functional layer is surmounted by at least one protective layer chosen from one or more of the following materials: Ti, TiOx, NiCr, NiCrOx, Nb , Ta, Al, Zr or ZnAl.

14. Glass sheet according to one of claims 1 to 13, characterized in that the layer (s) -s barrier (s) to the diffusion of oxygen is or are based on Si ₃ N ₄ , SiOxNy , AlN or AlOxNy.

15. Curved eVou tempered glass sheet formed of a sheet of glass carrying a multilayer stack according to one of claims 1 to 14 which has undergone a heat treatment eVou tempering bending after depositing the stack.

16. Laminated glazing comprising at least one glass sheet according to one of claims 1 to 15 joined to at least one other glass sheet with the intervention of a PVB film.

17. Multiple glazing comprising at least one glass sheet according to one of claims 1 to 15 maintained hermetically spaced from at least one other glass sheet by a spacer attached to the periphery between the glass sheets.